import copy
#a = ("a","b","c")
#a = ["a","b","c"]
a = {"a","b","c"}
b =a
c = copy.copy(a)
d = copy.deepcopy(a) # print(b)
# print(c)
# print(d)
# print(id(b))
# print(id(c))
# print(id(d))
"""
考点:
1.可变对象:列表和字典
2.不可变对象:一旦创建就不可修改的对象:元组,字符串,数字
"""
class Person: #类对象
x = 5
y = 6
def __init__(self,x,y):
self.x = x
self.y = y
print(self.x)
print(self.y)
def add(self):
return self.x +self.y
#实例对象
p = Person(1,2)
p.z = 9 # 实例变量
# print(p.z)
# #p1 = Person(3,4)
# print(Person.add(Person(3,4)))
# print(p.add())
# print("-------------------------")
# print(p.z)
# print(p.x) #实例变量
# print(p.y) #实例变量
# print("************************************")
# print(Person.x) # 类变量
# print(p.add())
"""
考点:
1.类对象和实例对象
2.类变量和实例变量
""" # a *args **kwargs
def function(a,*args,**kwargs):
print(type(a))
print(type(args))
print(type(kwargs))
print(a)
print(args)
print(kwargs)
# function(1,1,1)
# function(6,7,8,9,b=2,c=3,d=4) """
考点:
1.位置必须是一定的a,*args,**kwargs
2.类型分别是int,tuple,dict
""" import time
def runtime(function):
def get_now_time():
print(time.time())
function()
return get_now_time
@runtime
def run():
print("run") def runtime1(function):
def get_now_time(*args):
print(time.time())
function(*args)
return get_now_time
@runtime1
def run1(i):
print(i)
#run()
#run1(1)
# print("___________________________________") def runtime3(function):
def get_now_time(**kwargs):
print(time.time())
function(**kwargs)
return get_now_time
@runtime3
def run3(**kwargs):
print(kwargs)
#run3(a="aaa") def runtime4(function):
def get_now_time(name,**kwargs):
print(time.time())
function(name,**kwargs)
return get_now_time @runtime4
def run4(name,**kwargs):
print("名字==",name)
print(kwargs) #run4("jiyanjiao",a="haha") """
考点:
1.装饰器写法
2.不带参数装饰器
3.带参数的装饰器
""" def func1():
for i in range(1,5):
return i def func2():
for i in range(1,5):
yield i
# print(func1())
# print(func2()) # yi = func2()
# for i in yi:
# print(i) # print("**************************") re =func2()
# for i in re:
# print(i) """
考点:
1.yield 与 return区别
2.yield:生成器类型
""" # 题目:根据一个列表,创建一个新的列表,用一行代码
# lambada表达式 推导式 list1 = [1,2,3,4]
result = map(lambda x: x*x,list1)
# print(list(result))
# print("&&&&&&&&&&&&&&&&&&&&&&&&&&")
# 用推导式来解决,列表推导式
list2 = [i*i for i in list1]
#print(list2) list3 = [i*i for i in list1 if i>2]
#print(list3) # 集合的推导式 打印结果无序,因为集合是无序的
list1 = {1,2,3,4}
list4 = {i*i for i in list1}
#print(list4) #字典的推导式
dict1 = {
"key1":"value1",
"key2":"value2"
}
keys = [key for key ,value in dict1.items()]
#print(keys) key_value = {key:value for key,value in dict1.items()}
#print(key_value) key_value_if = {key:value for key,value in dict1.items() if key=="key1"}
#print(key_value_if)
"""
考点:
1.推导式 [表达式,for循环,条件]
""" '''
常见排序方式:
插入排序,希尔排序,直接排序,堆排序
冒泡排序,快速排序,归并排序,基数排序
'''
# 给定一个列表,将这个列表进行排序,要求:时间复杂度要小于o(n^2) '''
复杂度:
1.时间复杂度:指算法在计算的过程中所需要的计算工作量
2.空间复杂度:指算法在计算过程中所需要的内存空间
常见的时间复杂度:
常数阶O(1),对数阶O(log2n),线性阶O(n)
线性对数阶O(nlog2n),平方阶O(n^2),立方阶O(n^3)
随着问题的规模n,不断的增大,上述的时间复杂度就不断的增大,意味着算法的执行效率越低
''' #冒泡排序的实现
# 相邻的两个数字进行比较,大的向下沉,最后一个元素时最大的
# 时间复杂度O(n^2) def bublle_sort(blist):
count = len(blist)
for i in range(0,count):
for j in range(i+1,count):
if blist[i] > blist[j]:
blist[i],blist[j] = blist[j],blist[i]
return blist blist = [8,5,90,31,1]
s = bublle_sort(blist)
#print(s) """
快速排序:
思想:递归
列表中取出第一个元素作为标准,把比第一个元素小的都放在左侧,把比第一个元素大的都放在右侧
最小的在左边,最大的在右边,递归完成即排序结束
时间复杂度:O(nlog2n)
"""
# 使用递归+推导式写快速排序 def quick_sort(quick_list):
if quick_list==[]:
return []
else:
first = quick_list[0]
less = quick_sort([l for l in quick_list[1:] if l < first])
more = quick_sort([m for m in quick_list[1:] if m >=first])
return less + [first] + more
quick_list = [8,5,90,31,1]
print(quick_sort(quick_list))